Determining Optimal Measurement Time Points for SPAD and Canopy Temperature in Drought Tolerant Cotton (Gossypium hirsutum L.) Breeding


Özet Görüntüleme: 38 / PDF İndirme: 23

Yazarlar

DOI:

https://doi.org/10.5281/zenodo.11280512

Anahtar Kelimeler:

Drought stress, SPAD, canopy heat depression, cotton

Özet

This study investigates optimal physiological parameter measurement times in Gossypium hirsutum L. to assess the effects of drought stress. Observations of SPAD (Leaf Chlorophyll Content) and canopy temperature depression (CMD) were made at different growth stages, including Early Growth, Flowering, Bolling, and Boll Opening stages. These measurements were linked to yield and fiber quality parameters across the cotton grown stages.Data was analyzed using Principal Component Analysis (PCA) to uncover complex trait variations and genetic diversity under water-limited conditions. Specifically, PCA revealed significant variations in key traits such as yield and fiber quality under water stress conditions.Canopy temperature measurements highlighted the reliability of assessments made during specific stages, particularly the Bolling stage, for evaluating trait relationships.Leaf chlorophyll content (SPAD) analysis emphasized the significant correlation of SPAD4 with fiber elongation (FE) and lint percentage (LP).Overall, the results demonstrate the critical importance of timely SPAD and CMD measurements, especially during the Bolling stage (SPAD3 and CHD3), for understanding cotton traits under drought stress.These findings underscore the importance of strategic physiological parameter assessments in cotton breeding under challenging environmental conditions.

Referanslar

Abd El-Daim, I.A., Bejai, S., Meijer. J., 2019. Bacillus velezensis 5113 induced metabolic and molecular reprogramming during abiotic stress tolerance in wheat. Scientific Reports, 9(1): 16282.

Abtahi, M., Majidi, M. M., Mirlohi, A., 2019. Genotype selection for physiological responses of drought tolerance using molecular markers in polycross hybrids of orchardgrass. Plant Breeding, 138(6): 937-946.

Ahmad, M., Waraich. E. A., Shahid. H., Ahmad, Z., Zulfiqar. U., Mahmood. N., El Sabagh, A., 2023. Exogenously applied potassium enhanced morpho-physiological growth and drought tolerance of wheat by alleviating osmotic ımbalance and oxidative damage. Polish Journal of Environmental Studies, 32(5): 4447-4459.

Alam, M.K., 2014. Genetic correlation and path coefficient analysis in groundnut (Arachis hypogea L.). SAARC Journal of Agriculture, 12(1): 96-105.

Amani, I., Fischer, R.A., Reynolds. M.P., 1996. Canopy temperature depression association with yield of ırrigated spring wheat cultivars in a hot climate. Journal of Agronomy and Crop Science, 176(2): 119-129.

Arabacı, O., Tan, U., Yıldız, Ö., Tutar, M., 2017. Effect of different harvest times on some quality characteristics of cultivated sahlep orchid serapias vomeracea (Burm. fill.) Brig. International Journal of Secondary Metabolite, 4(Special Issue): 445-451.

Ata-Ul-Karim, S.T., Cao, Q., Zhu, Y., Tang, L., Rehmani, M.I.A., Cao, W., 2016. Non-destructive assessment of plant nitrogen parameters using leaf chlorophyll measurements in rice. Frontiers in Plant Science, 7: 1829.

Bahar, B., Yildirim, M., Barutcular, C., Genc. I., 2008. Effect of canopy temperature depression on grain yield and yield components in bread and durum wheat. Notulae Botanicae Horti Agrobotanici Cluj-Napoca, 36(1): 34-37.

Balkan, A., Bilgin. O., Başer. İ., Göçmen, D. B., Özcan, K., 2023. Study on some quality and morpho-physiological traits of durum wheat (Triticum durum L. Desf.) genotypes. ISPEC Journal of Agricultural Sciences, 7(1): 86-94.

Barik, S.R., Pandit, E., Mohanty, S.P., Nayak, D.K., Pradhan, S.K., 2020. Genetic mapping of physiological traits associated with terminal stage drought tolerance in rice. BMC Genetics, 21: 1-12.

Bennani, S., Nsarellah, N., Birouk, A., Ouabbou, H., Tadesse, W., 2016. Effective selection criteria for screening drought tolerant and high yielding bread wheat genotypes. Universal Journal of Agricultural Research, 4(4): 134-142.

Cakalogullari, U., Tatar, M.O., 2020. Adaptation of cotton (Gossypium hirsutum L.) to limited water conditions: reversible change in canopy temperature. AgroLife Scientific Journal, 9(1): 64-72

Chen, D., Wang, S., Cao, B., Cao, D., Leng, G., Li, H., Deng, X., 2016. Genotypic variation in growth and physiological response to drought stress and re-watering reveals the critical role of recovery in drought adaptation in maize seedlings. Frontiers in Plant Science, 6: 172337.

Conaty, W.C., Mahan, J.R., Neilsen, J.E., Tan, D.K.Y., Yeates, S.J., Sutton, B.G., 2015. The relationship between cotton canopy temperature and yield. fibre quality and water-use efficiency. Field Crops Research, 183: 329-341.

Guendouz, A., Frih, B., Oulmi, A., 2021. Canopy cover temperature & drought tolerance indices in durum wheat (Triticum durum desf.) genotypes under semi-arid condition in algeria. International Journal of Bio-Resource and Stress Management, 12(6): 638-644.

Hayano-Kanashiro, C., Calderón-Vázquez, C., Ibarra-Laclette, E., Herrera-Estrella, L., Simpson, J., 2009. Analysis of gene expression and physiological responses in three Mexican maize landraces under drought stress and recovery irrigation. PLoS one, 4(10): e7531.

James, L.G., 1988. Principles of farm irrigation systems design, s:544.

James, D., Borphukan, B., Fartyal, D., Ram, B., Singh. J., Manna, M., Reddy, M.K., 2018. Concurrent overexpression of OsGS1; 1 and OSGS2 genes in transgenic rice (Oryza sativa L.): impact on tolerance to abiotic stresses. Frontiers in Plant Science, 9: 307492.

Lanceras, J.C., Pantuwan, G., Jongdee, B., Toojinda, T., 2004. Quantitative trait loci associated with drought tolerance at reproductive stage in rice. Plant physiology, 135(1): 384-399.

Lopes, M.S., Reynolds, M.P., 2010. Partitioning of assimilates to deeper roots is associated with cooler canopies and increased yield under drought in wheat. Functional Plant Biology, 37(2): 147-156.

Magwanga, R.O., Lu, P., Kirungu, J.N., Cai, X., Zhou, Z., Agong, S.G., Liu, F., 2020. Identification of QTLs and candidate genes for physiological traits associated with drought tolerance in cotton. Journal of Cotton Research, 3: 1-33.

Mahan, J.R., Burke, J.J., 2015. Active management of plant canopy temperature as a tool for modifying plant metabolic activity. American Journal of Plant Sciences, 6(01):249.

Mason, R.E., Singh, R.P., 2014. Considerations when deploying canopy temperature to select high yielding wheat breeding lines under drought and heat stress. Agronomy, 4: 191-201.

Oğuz, I.K., 2021. Investigation of nitrate content of sage (Salvia fruticosa Mill) and Oregano (Origanum onites) Plants. ISPEC Journal of Agricultural Sciences, 5(1): 21-26.

Özkul, M., Ozkul, M., Mesut, O., Belge, A., Mutlu, D., 2022. Phenological development stages and effective temperature total demand in bursa siyahı fig variety. ISPEC Journal of Agricultural Sciences, 6(2): 260-271.

Sarwar, M., Saleem, M.F., Ullah, N., Ali, A., Collins, B., Shahid, M., Kumar, M., 2023. Superior leaf physiological performance contributes to sustaining the final yield of cotton (Gossypium hirsutum L.) genotypes under terminal heat stress. Physiology and Molecular Biology of Plants, 29(5): 739-753.

Shah, S.H., Angel, Y., Houborg, R., Ali, S., McCabe, M.F., 2019. A random forest machine learning approach for the retrieval of leaf chlorophyll content in wheat. Remote Sensing, 11(8): 920.

Singh, D., Balota, M., Isleib, T.G., Collakova, E., Welbaum, G.E., 2014. Suitability of canopy temperature depression. specific leaf area. and spad chlorophyll reading for genotypic comparison of peanut grown in a sub-humid environment. Peanut Science, 41(2): 100-110.

Suzuki, N., Rivero, R.M., Shulaev, V., Blumwald, E., Mittler, R., 2014. Abiotic and biotic stress combinations. New Phytologist, 203(1): 32-43.

Tang, Y., Zhang, J., Wang, L., Wang, H., Long. H., Yang. L., Shao, R., 2023. Water deficit aggravated the inhibition of photosynthetic performance of maize under mercury stress but is alleviated by brassinosteroids. Journal of Hazardous Materials, 443: 130365.

Zhang, H., Pan, X., Li, Y., Wan, L., Li, X., Huang, R., 2012. Comparison of differentially expressed genes involved in drought response between two elite rice varieties. Molecular Plant, 5(6): 1403-1405.

İndir

Yayınlanmış

2024-06-07

Nasıl Atıf Yapılır

GÖREN, H. K. (2024). Determining Optimal Measurement Time Points for SPAD and Canopy Temperature in Drought Tolerant Cotton (Gossypium hirsutum L.) Breeding. ISPEC Tarım Bilimleri Dergisi, 8(2), 449–460. https://doi.org/10.5281/zenodo.11280512

Sayı

Cilt 8 Sayı 2 (2024)

Bölüm

Makale

Lisans

Telif Hakkı (c) 2024 ISPEC Tarım Bilimleri Dergisi

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Bu çalışma Creative Commons Attribution-NonCommercial 4.0 International License ile lisanslanmıştır.